All subjects were men from Zhaoqing, Guangdong (China) and constituted three participants recruited for the research project entitled ‘Study of Rare Thalassemia Gene Mutations in the Zhaoqing Population’. Case 1 was a patient aged 32 years, with no family history of anemia. Prior to family planning, the patient underwent thalassemia screening at The First People's Hospital of Zhaoqing in January 2021. Routine hematological phenotyping revealed normal red blood cell (RBC), Hb, mean corpuscular volume (MCV) and mean corpuscular Hb (MCH) levels; Hb electrophoresis analysis demonstrated Hb Constant Spring (HbCS) bands. Routine genetic testing showed no abnormalities in thalassemia-related genes. Case 2 was a patient aged 56 years, who presented with a history of iron deficiency anemia and familial anemia. In July 2022, during a period of hospitalization at The First People's Hospital of Zhaoqing, thalassemia-related testing revealed reduced RBC, Hb, MCV and MCH levels in hematological phenotyping. Hb electrophoresis analysis indicated HbH disease and HbCS bands. Routine thalassemia gene testing revealed [-^{Southeast Asian (SEA)}/αα^{Quong Sze (QS)} (HBA2: c.377T>C)], β^N/β^N genotypes. Case 3 was a patient aged 31 years, with no family history of anemia. Routine hematological phenotyping conducted in March 2023 showed normal RBC, Hb, MCV and MCH levels. Hb electrophoresis and routine thalassemia gene testing were requested for fertility reasons. Hb electrophoresis alone revealed an HbX + HbA₂ abnormality.

The present study was approved by the Ethics Committee of Zhaoqing First People's Hospital (approval no. B2024-02-04) and was performed in accordance with the ethical principles for medical research involving human subjects as outlined in The Declaration of Helsinki. Written informed consent was obtained from all subjects prior to inclusion in this study, authorizing the publication of their clinical data and imaging materials.

The XN-1000 hematology analyzer and its accompanying reagents were purchased from Sysmex Corporation. The CAPILLARYS2 fully automated capillary electrophoresis system and its associated reagents, purchased from Sebia S.A., were used for Hb analysis. The Whole Blood Genomic DNA Extraction Kit (cat. no. 20240501), and α- and β-Thalassemia Gene Detection and Hybridization kits (cat. no. 20240501) were procured for thalassemia gene testing, and the HB-2012A medical nucleic acid molecular hybridization instrument (product no. YYC1801024) and HBNP-4801A automated extraction system (product no. YYD20201114) were purchased from Guangdong Kaipu Technology Co., Ltd. The Applied Biosystems Veriti™ Dx Thermal Cycler and 3730xl DNA Analyzer were purchased from Thermo Fisher Scientific, Inc. All relevant testing procedures were strictly performed in accordance with the instrument and kit manuals.

A total of four tubes of EDTA-K2-anticoagulated venous blood (2 ml/tube) were collected from each patient for use in complete blood count, Hb electrophoresis, thalassemia gene detection and sequencing.

RBC parameters were analyzed using the fully automated modular blood and body fluid analyzer XN-1000 and its corresponding reagents. Reference values for hematological parameters in adult men are listed in Table I.

Peripheral blood Hb electrophoresis was performed using the CAPILLARYS 2 fully automated capillary electrophoresis system. Electrophoresis patterns were divided into zones Z1-Z15 to identify and analyze the proportion of each band, with primary focus on fetal Hb bands and HbA₂ bands. The presence of abnormal Hb and its potential type were determined based on the region where the Hb peak pattern was located. Analyses of abnormal Hb peaks were performed with reference to the abnormal Hb distribution spectrum provided by Sebia S.A. The reference ranges for Hb electrophoresis components are listed in Table I.

Human genomic DNA was extracted from 200 µl whole blood samples using an automated extraction system and matching extraction reagents. The concentration of the extracted DNA was then determined by measuring the absorbance at 260 nm using an ultraviolet spectrophotometer.

Thalassemia gene detection employs gap PCR and multiplex PCR amplification techniques, using the α- and β-thalassemia gene detection and hybridization kits. The primer sequences, including probes on the hybridization membrane strips (Tables SI and SII), and reaction systems used in the present study are described in a previous study (34). Through the flow-through hybridization method, three common deletion-type α-thalassemia classifications prevalent in the Chinese population were simultaneously detected: -α^3.7 (rightward), -α^4.2 (leftward) and -^SEA, and three mutation-type α-thalassemia classifications were detected: HbCS (HbCS or HBA2: c.427T>C), Hb QS and Hb Westmead (Hb WS or HBA2: c.369C>G). In addition, 15 common β-thalassemia classifications in the Chinese population were detected: -29 (A>G) (HBB: c.-79A>G), -28 (A>G) (HBB: c.-78A>G), CAPM (-AAAC) (HBB: c.-50A>C), InitM (ATG>AGG) (HBB: c.2T>G), codons 14/15 (+G) (HBB: c.45_46insG), codon 17 (AAG>TAG) (HBB: c.52A>T), codon 26 (GAG>AAG) (HBB: c.79G>A), codons 27/28 (+C) (HBB: c.84_85insC), codon 31 (-C) (HBB: c.94delC), intron variant site (IVS)I-1 (G>A, G>T) [HBB: c.92+1(G>T)], IVSI-5 (G>C) (HBB: c.92+5G>C), 41/42M (-TTCT) (HBB: c.126_129delCTTT), codon 43 (GAG>TAG) (HBB: c.130G>T), codons 71/72 (+A) (HBB: c.216_217insA) and IVSII-654 (C>T) (HBB: c.316-197C>T). The probe arrangement on the hybridization membrane strips is shown in Table II.

Briefly, after nucleic acid extraction, the detection process requires multiplex PCR amplification and flow cytometric hybridization to be completed. First, multiplex PCR amplification was performed, which involves two reaction systems. α-Thalassemia PCR (Reaction System 1) comprised a 50-µl reaction volume containing 100 ng DNA template, 25 µl 2X GC buffer, 4 mmol/l MgCl₂ and 0.2 mmol/l each primer (34), 0.2 mmol each dNTP and 2.5 units HotStart DNA polymerase. This was performed on an Applied Biosystems Veriti™ Dx Thermal Cycler (Applied Biosystems; Thermo Fisher Scientific, Inc) under the following program: Denaturation at 95˚C for 15 min, followed by 35 cycles at 98˚C for 40 sec, 64˚C for 70 sec and 72˚C for 150 sec, and a final extension step at 72˚C for 5 min. β-Thalassemia PCR (Reaction System 2) was performed in a 50-µl reaction mixture containing 100 ng DNA template, 5 µl 10X buffer, 3.5 mmol/l MgCl₂, 0.2 mmol/l each primer (34), 0.2 mmol/l each dNTP, 2.5 units DNA Taq polymerase and 1 unit uracil DNA glycosidase. The PCR conditions were as follows: 5 min at 37˚C, 3 min pre-denaturation at 94˚C, followed by 40 cycles of denaturation at 94˚C for 30 sec, annealing at 55˚C for 30 sec and extension at 72˚C at 30 sec, with a final 5-min extension at 72˚C. Amplification products from both reaction systems were subsequently denatured and subjected to hybridization analysis. Flow hybridization was performed using the α- and β-thalassemia gene hybridization kit (Guangdong Kaipu Technology Co., Ltd.), strictly adhering to the manufacturer's protocol. This assay employs Hybribio's proprietary flow hybridization technology [U.S. Patents 5,741,647(35) and 6,020,187(36)], which actively guides target molecules toward membrane fibers containing immobilized probes, trapping complementary molecules after double-strand formation. Following rigorous washing steps, hybridization products are detected by adding streptavidin-horseradish peroxidase conjugate. This conjugate binds to biotin-labeled PCR products, generating a blue-violet precipitate at probe locations via the substrate (nitroblue tetrazolium-5-bromo-4-chloro-3-indolyl phosphate). Results are interpreted by direct visual inspection.

Peripheral blood DNA was extracted using a whole blood genomic extraction kit. Amplification was then performed using Gap-PCR and multiplex PCR. The amplified products underwent agarose gel electrophoresis on 1.0% (w/v) gels, which were developed using 0.5 µg/ml ethidium bromide solution, to confirm the target fragment, which was subsequently sent to Guangdong Kaipu Technology Co., Ltd. for sequencing analysis of rare thalassemia genes using the Sanger double-deoxy chain termination method. The amplification primers (Table SIII) and reaction conditions used in the present study are described in previous studies (37,38). Detected gene sequences were annotated against the databases HbVar (http://globin.bx.psu.edu/hbvar) and Ithanet (https://www.ithanet.eu/) to determine the type of mutation detected. All experimental procedures were strictly performed in accordance with standard operating procedures.

Patient hemolytic anemia characteristics and hematological parameters are presented in Table I. Case 1 exhibited normal RBC, Hb, MCV and MCH levels, but reduced HbA₂ and elevated HbCS levels (Fig. 1A). The routine hemolytic anemia gene testing results were as follows: Undetected, but a faintly stained circle appeared at the position indicated by the arrow on the hybridization membrane strip (Fig. 1B). Case 2 exhibited reduced levels of RBC, Hb, MCV and MCH. Hb electrophoresis revealed decreased HbA and HbA₂, with abnormal bands HbH and HbCS visible (Fig. 1C). The routine thalassemia gene testing results were as follows: -^SEA/αα^QS, β^N/β^N (Fig. 1D), confirming HbH disease. Case 3 exhibited normal RBC, Hb, MCV and MCH levels, but elevated HbX + HbA₂ levels, due to inherent methodological limitations of the instruments and reagents employed during the study design phase, it was not possible to separate HbA₂ from HbX. Consequently, it was not feasible to calculate the HbA₂ value independently (Fig. 1E). The routine thalassemia gene testing results were as follows: Not detected (Fig. 1F).

Sequencing of the α1 globin gene in case 1 revealed no rare genotypes. Sequencing of the α2 globin gene identified a heterozygous mutation at the HBA2:c.*71 G>C (3'UTR +71 G>C) locus, representing a rare genotype reported for the first time in the Chinese population, to the best of our knowledge. Sequencing of the β globin gene detected no abnormal genotypes. Consequently, this patient exhibited α-thalassemia with the rare α-gene genotype αα/αα^{3'UTR +71 G>C} heterozygosity (Fig. 2A).

The routine thalassemia gene testing of case 2 yielded results of -^SEA/αα^QS, with no rare thalassemia mutation types detected in either the α1 or α2 globin gene; however, the β globin gene sequencing revealed a rare heterozygous mutation: ^{βIVSII-672 A>C/βN} (HBB:c.316-179 A>C). Therefore, this patient exhibited compound α,β-thalassemia (Fig. 2B), characterized by the genotype -^SEA/ααQS combined with ^{βIVSII-672 A>C/βN}. This combination of thalassemia genotypes represents the first reported case in the Chinese population, to the best of our knowledge.

No rare genotypes were detected in the α1 globin gene sequencing of case 3; however, sequencing of the α2 globin gene revealed a heterozygous mutation at the HBA2:c.82 G>A (CD 27 GAG>AAG) site (Fig. 2C). The β globin gene sequencing revealed a heterozygous mutation at the HBB:c.315+180 T>C (IVSII-180 T>C) locus (Fig. 2D), representing a previously unreported rare genotype, to the best of our knowledge. Consequently, this patient exhibited a heterozygous double rare genotype for αα/αα^{CD 27 GAG>AAG} heterozygous compound β^{IVSII-180 T>C}/β^N double rare thalassemia genotype. This combination represents the first reported case in the Chinese population, to the best of our knowledge.